RU2175058C2 - Process of action on face zone of pool and gear for its implementation - Google Patents

Abstract

FIELD: industrial exploitation and restoration of productivity of wells under complicated conditions of development. SUBSTANCE: process of action on face zone of pool includes vibration-wave action and simultaneous periodic reduction of pressure on face below seam pressure. Vibration-depression action is implemented in turn on each perforation conduit or group of perforation conduits with local excitation of elastic vibrations right in them and with local reduction of pressure below seam pressure across inlet and inside perforation conduits. Gear for implementation of process includes lowered hollow body and cylindrical flow chambers hydraulically coupled to it. Each chamber is fitted with swirler of liquid flow, pressure nozzle, outlet toroidal chamber with outlet nozzle. EFFECT: increased efficiency of cleaning of face zones of pool. 9 cl, 2 dwg

Description

 The invention relates to the oil industry and can be effectively used to develop and restore well productivity in difficult development conditions, in particular, it can be used in production processes for liquidation in the bottom-hole formation zone (PZP) and perforation channels of solid sediments of salts, paraffins, asphalt - resinous deposits and gas hydrates.

 A known method and device for acoustic stimulation of wells in complicated conditions (US Pat. USA N 4702315, CL 166-249).

 The disadvantage of this analogue is the low efficiency of the restoration of the filtration properties of the PPP.

 There is a method of acoustic impact on the PPP, including the allocation of areas with reduced filtration properties and sequential pointwise, from top to bottom, treatment of the formation by repeated exposure to an acoustic field (RF, Patent N 2026969, class E 21 B 43/25, B.I. 2 95 g.).

 The disadvantage of this analogue is the low efficiency of development, as well as the cleaning of wells with highly contaminated, up to a complete loss of productivity, bottom-hole zone.

 The closest technical solution adopted for the prototype is a method for processing PZP, including vibrating microwave and at the same time periodically lowering the pressure at the bottom of the reservoir (PCT Application WO 95/29322, 95 g).

 The disadvantage of this method is that it does not provide, when exposed, the optimal conditions for the transfer of elastic vibrational energy from the well to the perforation channels and further to the PPP. When vibrational processes are excited in a borehole fluid, there is a strong frequency limitation on the radiation of energy into the environment of the well (Krutin V.N. Energy ratios for the emission of elastic waves from a borehole // New geoacoustic methods for research, prospecting and exploration of mineral deposits: Sat. - M.: VNIIAGG, 1982. - S. 76-88). If the frequency of the excited oscillations is below a certain critical frequency, then the well filled with liquid is a waveguide for them, and energy in the form of elastic waves from the well is not radiated or is radiated weakly, only when the tube wave propagating in the well waveguide is absorbed through irregularities - perforation channels. For real wells, the critical frequency is at least 20 KHz, which is outside the optimal field of excitation, the low-frequency range of 1-500 Hz, which is most effective for affecting the BFZ due to the weak attenuation of low-frequency waves in a porous saturated medium, and because of the manifestation a number of strong, purely low-frequency effects of softening of porous colmatants, cleaning and changing the filtration characteristics of a porous medium. For the above reasons, the known method does not provide the most effective cleaning of the bottomhole formation zone, decolmatization and washing of the pore openings and cracks in the well filter, dispersion and destruction of contaminating deposits and structures in the fluid-output channels. The recovery of the initial permeability of the bottomhole formation zone after overhaul of the wells is not fully ensured, the natural filtration characteristics of the bottomhole formation zone after the development of wells removed from drilling, as well as long-term and inactive wells, are not sufficiently restored.

 In addition, a sufficiently deep decrease in pressure in the entire volume of the bottomhole during processing significantly complicates the technological operations of the method, requires the use of powerful wellhead pumping equipment, and, in addition, can adversely affect the stability of the well attachment.

 A device is also known for influencing the bottom-hole zone of the formation (EP N 0512331, IPC E 21 B 21/00, 92 g.), Comprising a hollow body with a host located therein, designed to generate hydrodynamic waves, in which the vortex chamber, which is a continuation of the axial direction of the hollow body is connected with the cavity of the hollow body by means of tangentially located input channels, and there is at least one additional vortex chamber, which is located in the direction of flow in front of the main vortex chamber, is connected with the cavity of the hollow body ate via tangentially disposed entrance channels and comprises two conically tapering, oppositely directed output channels which extend exactly perpendicular to the axial direction of the hollow body.

 However, the known device does not allow to obtain a significant effect on the bottom hole, especially in heavily contaminated, long-flowing and inactive wells, as it does not provide the generation of high-amplitude low-frequency oscillations and the optimal transfer of their energy from the well to the bottom-hole zone, and also does not provide optimal indicators of pressure reduction and its locality in cultivated bottom-hole zones.

 The objective of the invention is to increase the efficiency of development, cleaning of the bottomhole formation and restoration of well productivity by expanding the frequency range of the effective impact, reducing energy consumption, simplifying and improving the reliability of the method and device.

 The problem is achieved in that in the known method of exposure to the bottomhole formation zone, including vibrating microwave action and at the same time periodically lowering the pressure at the bottom below the reservoir, according to the invention, the vibration-depression effect is performed alternately on each perforation channel or group of perforation channels of the well with local excitation directly in them elastic vibrations and with local only at the entrance and inside the perforation channels pressure drop below the reservoir.

 It is advisable to sort the exposed perforation channels by moving the local impact areas along the perforation interval from top to bottom or bottom to top with simultaneous rotation around the axis of the well. It is also advisable to automatically adjust the area of influence on the perforation channel or group of perforation channels of the well.

 It is advisable to carry out the aforementioned vibrational and depressive effects by a hydrodynamic vortex generator by pumping into it from the wellhead under pressure of a liquid or gas-liquid mixture. Hydrodynamic vortex generators, based on the use of pulsations of vortex flows, very efficiently use the kinetic energy of the liquid, and in addition, vortex flows are able to carry out significant pressure reductions in local areas. When using a hydrodynamic vortex generator, the conditions for flushing the well improve, standard oilfield equipment is optimally used, and compatibility with many regular technological operations for developing and repairing wells appears.

 In especially complex cases of severe contamination of the perforation channels of the well and the bottomhole formation zone, with significant depletion of the reservoir potential, an abnormally low reservoir pressure, it is advisable to fill the annular space of the well with foam by vibrating-depressing effects by adding a foaming agent to the gas-liquid mixture injected into the generator. At the same time, the depth of depression in the processed perforation channels of the well and the bottom hole significantly increases, the conditions for removing contaminants from the bottom hole and bring them to the surface improve, the functionality of the method is expanded - it becomes possible to carry out a depressive effect in deep wells, in wells with depleted and abnormally low formation pressure .

 The task is also achieved by the fact that in the known device containing a hollow body that is run down on pipes and flow chambers hydraulically connected to it and arranged perpendicular to the axial direction of the hollow body, according to the invention, the flow chambers are cylindrical, mounted in the body with an axial intersection with its central axis , and each flow chamber is equipped with a centrally located central swirl of fluid flow, a pressure nozzle and an output toroidal vortex chamber with an outlet nym nozzle, wherein the end surfaces of the flow chambers are installed with equal gap relative to the inner surface of the well string.

 To expand operational capabilities, it is advisable to implement a device with the possibility of spontaneous rotation of the housing with cylindrical flow chambers mounted on it around its axis during operation initiated by injection of the working agent.

 To expand operational capabilities, the range of regulation of the device and optimize its operation, it is advisable that the cylindrical flow chambers are installed with the possibility of their axial movement relative to the housing of the device.

 It is advisable to perform the central swirl of the cylindrical flow chamber in the form of a screw. In this case, in comparison with the known invention, the abrasive wear of the vortex-forming channels is reduced, the reliability of the device is increased.

 The claimed method implements a more effective mechanism for exciting self-oscillations in the well and transferring vibrational energy to the bottomhole zone, associated with the occurrence of intense low-frequency pulsations in the perforation channels of the well. Directly in the volume of the medium of the bottom-hole zone there arises one or at the same time a group of monopolistic emitters that create spherically symmetrical waves in the surrounding rocks. Such a radiator, in contrast to the radiator of the known invention, emits quite efficiently in a wide range of low frequencies. There is a high-quality transfer of impact energy from the well to the formation. The depth of the effective impact on the PPP is increasing. With simultaneous excitation of a group of perforation channels, the acoustic radiation power increases in proportion to the square of their number. Moreover, a completely new result is achieved - the creation of a vibration-depression effect on the area of the inner surface of the casing with perforations in them. At the same time, pressure decreases significantly in perforation channels, and pressure gradients directed to the well are created in the most contaminated PZP sections adjacent to the perforation channels, which contribute to the removal of contaminants and blocking phases from the porous medium.

 Local pressure reduction directly in the perforation channels does not require attracting significant capacities of wellhead pumping units and creating increased discharge pressure in the descent pipes, which allows to reduce energy consumption and increase the reliability of the method.

 Under the influence of low-frequency elastic vibrations and pressure drops, softening and dispersing of plugs and particles of colmatant, softening of clay inclusions, effective cleaning of perforation channels, pores and cracks of the BFZ collector occurs, the blocking effect of the residual phases of gas, oil and water is eliminated, fluid filtration in low-permeability layers is initiated and formation zones. The coverage of the reservoir increases both in thickness and in strike. The productivity of the wells put into operation after drilling is increased, the injectivity of injection wells is increased, the productivity coefficient and the initial filtration characteristics of oil wells are restored and increased after their repair.

 The proposed device allows you to create one or a group of torus fluid vortices with an axis of rotation directed normal to the surface of the column on the inner surface of the well string, near the exposed perforation channel or group of perforation channels. With a sufficient tangential velocity of the fluid in the central region of the vortex, due to the well-known vortex hydrodynamic effect, the pressure decreases to 0.3 - 0.5 of the value of the surrounding bottomhole pressure. At the same time, for a certain gap between the cylindrical flow chamber of the device and the inner surface of the well string, the low-pressure region pulsates intensively with a frequency of 20-250 Hz, depending on the fluid flow rate and the geometric parameters of the device. When the device body is rotated and moved along the perforation interval, the central regions of the excited pulsating vortices cover alternately the inlet openings of the perforation channels of the well filter. In the perforation channel or group of perforation channels, local intense pulsating depressions are created and an effective effect on the PPP is carried out.

 In FIG. 1 shows a device for implementing the method.

 In FIG. 2 - an embodiment of the device with the possibility of spontaneous rotation of the housing when pumping the working fluid.

 Since the claimed method is implemented when the claimed device for processing a PPP, the description of the method is given in the presentation section of the description of the operation of the device.

 The device for influencing the PPP comprises a hollow body 1, hydraulically flowing cylindrical chambers 2 mounted therein and a central swirl chamber 3 with a central swirl 3, a discharge nozzle 4, an output toroidal swirl chamber 5 with an output nozzle 6. The central swirl 3 is auger, but can be any type, for example with screw or tangential twist channels. The output surfaces of the cylindrical flow chambers 2 are installed in the well with an equal gap 7 relative to the inner surface of the column 8, the value of which, in order to optimize the work, can be controlled by the axial movement of the cylindrical flow chambers in the housing 1 of the device. The cavity of the housing 1 is connected to a pressure line for supplying a working fluid under pressure.

 To implement spontaneous rotation of the hollow body 1, initiated by the injection of the working fluid, tangential channel 9 is possible in its wall.

 The method is as follows.

 Through the pipes lowered into the well, the liquid working agent is pumped under design pressure and speed into the hollow body 1 and then into the cylindrical flow chambers 2 of the device according to the invention. Flowing through the central swirl 3, the liquid forms a liquid vortex inside the cylindrical flow chamber 2, which, passing through the pressure nozzle 4 and the output toroidal vortex chamber, is ejected through the output nozzle 6 to the bottom towards the surface of the borehole and then passes through the annulus to the wellhead . In the absence of an external “load”, when the gap 7 between the output end surface of the cylindrical flow chamber and the column wall is sufficiently large, no significant pressure pulsations in the center of the vortex occur. The region of intense rotation “slips” the output vortex toroidal chamber and concentrates mainly in the rotating cone at the outlet of the cylindrical flow chamber 2. With a certain decrease in the gap 7, an intense self-oscillating process occurs. In the first phase of the process, a liquid vortex, passing through the pressure nozzle 4, develops in the gap 7, forming a flat toroidal expanding vortex. In this case, the pressure in its central part decreases with a decrease in the radius of the vortex, and increases at the periphery of the vortex due to centrifugal and friction forces in the narrow gap 7. With a certain increase in pressure at the periphery of the vortex in the gap 7, the vortex jumps back to the output toroidal vortex chamber 5. In this phase of the process, the vortex movement at the outlet in the gap 7 substantially decreases, and the pressure in the central output part increases stepwise. With the development of the vortex in the outlet toroidal vortex chamber 5, the pressure also sharply increases in its peripheral part, which in turn leads to a jump-like movement of the vortex again to exit from the cylindrical flow chamber 2 into the gap 7. The above phases during the operation of the device are repeated many times, providing the development of intense pressure pulsations in the Central region of the gap 7 relative to the value of 0.3 - 0.5 from the external bottomhole pressure. A low self-oscillation frequency of 50 - 250 Hz is provided in the mechanism described above by a sufficiently large characteristic time of the vortex formation process in the output toroidal vortex chamber 5 and the gap 7. The frequency of exposure can be controlled by changing the geometric dimensions of the device chambers and the rate of fluid supply to its flow channels.

 When the housing rotates together with the vortex chambers placed on it and when the device moves along the perforation interval, the central pulsating regions of the vortices periodically cover the inlet openings of the perforation channels of the well. At the same time, in the channel fluid and in the closely located, most contaminated areas of the productive rock, the pressure decreases significantly, ensuring straining and the influx of contaminants into the well. At the same time, a channel or a group of channels becomes effective emitters of vibrational energy, while the radiation power from the well increases and the depth and degree of vibration exposure increase significantly.

 Spontaneous rotation of the housing can be accomplished by diverting a certain flow rate of the working fluid pumped into the device into the tangential channel 9 (Fig. 2) located in the wall of the hollow housing.

 By adjusting the flow rate of the fluid through the tangential channel 9, the areas of vibration-depression effect on the perforation channel or group of perforation channels of the well string 8 are automatically adjusted. When the housing rotates spontaneously and when the central region covers the vortices of the inlet openings of the perforation channels, the rotation resistance changes, so that when the flow rate is adjusted through tangential channel 9 rotation stops. In this case, up to the subsequent movement of the device along the perforation interval, the perforation channels of the well are directly affected. The movement of the device resumes the spontaneous rotation of the housing until the next automatic search for the inlet holes of the perforation channels.

 An example of a specific implementation of the method.

 The production well of the Arlan field immediately after its development after drilling was 12 tons / day. After 18 months of operation, the flow rate of the well fell to 3.5 tons / day. The reservoir pressure did not change and amounted to 9.5 MPa. The depth of the productive formation is 1100 - 1110 m. The reservoir reservoir is porous-cavernous limestone, the permeability is 80-100 mD. The diameter of the column is 5 ".

 A device for impacting the bottom hole together with a centralizer is lowered into the well at 2.5 "tubing to the perforation interval. The axial displacement of the cylindrical flow chambers is used to control the gaps of their end surfaces relative to the inner surface of the column and set the required estimated gap value. wells with a pumping unit ЦА-320 according to the scheme, allowing the circulation of fluid through the pipes and the annulus of the well. 0 MPa and a flow rate of 8.5 l / s, the well is processed for 4 hours. Throughout the entire time the pipe is admitted, the device moves down the perforation interval, while the device’s body rotates spontaneously under the influence of the injected fluid. -pressure effect of perforation channels at a bottomhole pressure of 11.0 MPa, the pressure decreases to a value of 5.5 MPa, providing a value of depression in the perforation channels of a well of 4.0 MPa.

 As a result of the treatment, the flow rate of the well is 10.5 tons / day.

Claims (9)

 1. A method of influencing the bottom-hole zone of the formation, including vibrating microwave action and simultaneously periodically lowering the pressure at the bottom of the formation, characterized in that the vibration-depression effect is carried out alternately on each perforation channel or group of perforation channels of the well with local excitation of elastic vibrations directly in them and with local only at the entrance and inside the perforation channels pressure drop below the reservoir.  2. The method according to claim 1, characterized in that the vibration-depression effect on each perforation channel or group of perforation channels is carried out along the perforation interval from top to bottom or from bottom to top with simultaneous rotation around the axis of the well.  3. The method according to claim 1 or 2, characterized in that under the aforementioned exposure, automatic tuning to the perforation channel or group of perforation channels is carried out.  4. The method according to claim 1, characterized in that the aforementioned effect is carried out by a hydrodynamic vortex generator by pumping into it from the wellhead under pressure of a liquid or gas-liquid mixture.  5. The method according to claim 1 or 4, characterized in that at the same time as the aforementioned impact, the well is filled with foam by adding a gas-liquid mixture of foaming agent to the pumped into the hydrodynamic vortex generator.  6. A device for influencing the bottom-hole zone of the formation, comprising a hollow body lowered by pipes and flow chambers hydraulically connected to it, perpendicular to the axial direction of the hollow body, characterized in that the flow chambers are cylindrical, installed in the body with an axial intersection with its central axis , and each flow chamber is equipped with a centrally placed central swirl of fluid flow, a pressure nozzle and an output toroidal vortex chamber with an output nozzle, etc. This end surfaces with flow chambers set equal to a gap relative to the inner surface of the well string.  7. The device according to claim 6, characterized in that it is made with the possibility of spontaneous rotation of the housing together with cylindrical flow chambers around its axis during operation.  8. The device according to claim 6 or 7, characterized in that the cylindrical flow chambers are made with the possibility of their axial movement relative to the housing of the device.  9. The device according to any one of claims 6 to 8, characterized in that the central swirl of the cylindrical flow chamber of the device is made in the form of a screw.

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